## Method 1:

Simplest way is to use the binomial coefficients. With this method, you have 1 recursive method:

```
// Here is your recursive function!
// Ok ok, that's cheating...
unsigned int fact(unsigned int n)
{
if(n == 0) return 1;
else return n * fact(n - 1);
}
unsigned int binom(unsigned int n, unsigned k)
{
// Not very optimized (useless multiplications)
// But that's not really a problem: the number will overflow
// way earlier than you will notice any performance problem...
return fact(n) / (fact(k) * fact(n - k));
}
std::vector<unsigned int> pascal(unsigned n)
{
std::vector<unsigned int> res;
for(unsigned int k = 0; k <= n; k++)
res.push_back(binom(n,k));
return res;
}
```

Live example.

## Method 2:

This method use the construction with the formulae:

Here, the only function is recursive and compute one line at a time, storing these result in an array (in order to cache results).

```
std::vector<unsigned int> pascal(unsigned int n)
{
// This variable is static, to cache results.
// Not a problem, as long as mathematics do not change between two calls,
// which is unlikely to happen, hopefully.
static std::vector<std::vector<unsigned int> > triangle;
if(triangle.size() <= n)
{
// Compute for i = last to n-1
while(triangle.size() != n)
pascal(triangle.size());
// Compute for n
if(n == 0)
triangle.push_back(std::vector<unsigned int>(1,1));
else
{
std::vector<unsigned int> result(n + 1, 0);
for(unsigned int k = 0; k <= n; k++)
{
unsigned int l = (k > 0 ? triangle[n - 1][k - 1] : 0);
unsigned int r = (k < n ? triangle[n - 1][k] : 0);
result[k] = l + r;
}
triangle.push_back(result);
}
}
// Finish
return triangle[n];
}
```

Live example.

## Others methods:

There are some other exotic methods, using the properties of the triangle. You can also use the matrix way to generate it:

No code for it, as it would require a lot of base code (matrices, exponential of matrix, etc...), and it is not really recursive.

*On a side note, I think this problem is absolutely not the right problem to teach recursion. There are a lot of better cases for it.*